Method of changing processor-generated individual characterizations presented on multiple interacting processor-controlled objects

ABSTRACT

Processor-controlled objects, such as inter-communicating processor-controlled blocks, are adapted to present changeable individual characterizations to a user. A user manipulating the objects can cause, over time, a designated object to inherit characterizations and properties from other interacting objects to permit scalability in a set of such objects. The communication of individual characterization between interacting objects allows generation of sensory responses (in a response generator of a specific object or otherwise in a response generator associated with at least one other similar objects) based on proximity, relative position and the individual characterization presented on and by those interacting objects at the time of interaction. In this way, a set of objects has vastly extended interactive capabilities since each object is capable of dynamically taking on different characterizations arising from a meaningful combination of properties from different conjoined objects.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 11/142,955, filed on Jun. 2, 2005, entitled “MANIPULABLE INTERACTIVE DEVICES,” which is incorporated herein by reference in its entirety for all purposes.

FIELD OF THE INVENTION

This invention generally relates to processor controlled objects, such as inter-communicating processor-controlled blocks. More particularly, the present invention is directed to a controllably presenting changeable, processor-generated individual characterizations presented on each of a plurality of objects that selectively interact.

BACKGROUND OF THE INVENTION

This invention relates to a manually manipulable device, especially a device which is adapted to interact with a similar device or devices according to their relative locations so as to produce a sensory response for a user, such a device being especially suitable for educational or entertainment purposes.

SUMMARY OF THE INVENTION

The present invention generally comprises a method of using processor controlled objects including controllably presenting changeable, processor-generated individual characterizations presented on each of a plurality of processor-controlled objects to present changeable individual characterizations to a user. A user manipulating the objects can cause, over time, designated objects to inherit characterizations and properties from other interacting objects. Interactions further generate sensory responses in the response generator of a specific object or otherwise in a response generator associated with another similar object based on proximity, relative position and the individual characterization presented on and by those interacting objects at the time of interaction. A set of objects has extended interactive capabilities since each object is capable of dynamically taking on different characterizations arising from a meaningful combination of properties from different conjoined objects.

In one embodiment of a method of controllably presenting changeable, processor-generated individual characterizations presented on each of a plurality of objects that selectively interact includes generating and displaying under powered processor-control first visual display material on a first movable object. The first visual display material has a first changeable individual characterization having a first property. The method includes sensing proximity and relative position of second visual display material generated and displayed under powered processor-control on a second movable object separate to the first movable object. The second object is brought into processor-resolvable interacting proximity with the first moveable object by manipulation of one or more of the first movable object and the second movable object. The second visual display material has a second changeable individual characterization independent to the first individual characterization and the second changeable individual characterization has a second property. In response to processor-resolved interaction between the first and second changeable individual characterizations arising from sensed proximity and relative position of the first and second objects, the method includes generating a user-perceivable sensory response from a response generator, wherein the user-perceivable sensory response is dependent upon the sensed relative positions of the first visual display material to the second visual display material and is indicative of a contextual relationship that arises between said first property of the first changeable individual characterizations and the second property of the second changeable individual characterizations. The method also includes under processor-control, selectively and autonomously changing with time the individual characterizations on at least one of the first and second objects such that the first property and the second property change to allow different processor-resolvable interactions to take place between the first and second objects, which different processor-resolvable interactions give rise to new user-perceivable sensory responses.

According to a first aspect, the invention consists of a manually manipulable device adapted to present an individual characterisation to a user comprising a processor, a power source, a communications unit, a response generator, and a proximity sensor adapted to sense the close proximity of a similar device, such that a user can manipulate the device and generate a sensory response in said response generator or a response generator of a similar device, in accordance with the proximity of one or more similar devices.

According to still another aspect, the invention consists of a set of two or more manually manipulable devices, each adapted to present an individual characterisation to a user and to be locatable relative to other such devices in multiple different arrangements, wherein each device comprises a processor, a power source, a response generator, and a communications unit, such that the devices generate a sensory response through said response generators in accordance with the arrangement of the devices selected by a user.

The characterisation may comprise visual display material or audio output material, and will vary depending on the particular application or purpose of the device or devices. For example, visual display material may comprise a letter or group of letters (e.g. phoneme) or word or words, and the sensory response may comprise speech corresponding to a word or phrase or sentence spelt out by the letters or words. In another application, visual display material may comprise a number or mathematical symbol, and the sensory response may comprise speech relating to mathematical properties of the numbers on the devices. In yet another application, visual display material may comprise a musical symbol and the sensory response may be an audio musical response. In an example in which the characterisation comprises audio output material, this may comprise the audio equivalent of any of the examples of visual display material given above.

In some implementations of the invention, the sensory response comprises an audio response which may be generated by one or more devices. Thus, each device incorporates an audio generator to provide an audio response. However, in other examples of the invention, the sensory response may instead, or in addition, comprise a visual response, which may be generated by one or more devices.

In a preferred embodiment of the invention, each device incorporates a visual display unit which displays visual display material and/or is able to generate a visual sensory response, which may be a static or animated visual display. Preferably, each device is programmable to allow the visual display material and the sensory response to be programmed to suit different applications, for example, to accommodate letters or words or numbers or musical symbols as described above, or any other visual display material, and to generate corresponding audio or visual responses.

Therefore, a device according to the invention is preferably a fully programmable, multifunctional device which can be adapted for use as a learning aid in relation to language, mathematics or music or other subjects. Such a device can be readily adapted to be used in the manner of known multi-component, educational apparatus such as Cuisinaire rods (used to teach arithmetic), dominoes and jigsaws, each component (rod, domino or jigsaw piece) being embodied in the form of a device according to the invention, which is then able to respond visually or audibly to enhance the experience of the user of the apparatus.

The communications unit incorporated in the device is adapted to communicate with similar devices with which it is used to co-ordinate the sensory response appropriate to an array of multiple devices. Each device communicates relevant information about itself corresponding to its characterisation and may be a simple identity code. The sensory response is made evident through one or more of the devices, and could include a separate response generator.

Communication of a sensory response to any device preferably occurs via the communications unit.

Preferably, the communications unit is a wireless device, that may be implemented using mobile telephone technology or the like.

Each device is preferably provided with a proximity sensor, or multiple proximity sensors, adapted to sense the proximity of a similar device in any one of multiple adjacent positions, for example, adjacent to each of multiple edges of the device. Each device is preferably further adapted to identify an adjacent device and to communicate information of both the identity and position of an adjacent device to other devices or to the central control unit via said communication unit so that an appropriate response can be generated.

The proximity sensor may comprise a magnetic or an electrical device, and may require physical contact between adjacent devices to be operational.

Preferably, a manually manipulable device according to the invention is constructed with a robust outer casing suitable for handling by a child aged 3 or older.

Preferably, a manually manipulable device according to the invention has registration features, such as protrusions and indents, in its outer surface that allow the device to be placed in registration with other such devices. Preferably, the registration features provide a visual guide during the registration process. The registration features may interlock adjacently located manually manipulable devices according to the invention. In one embodiment, a manually manipulable device according to the invention is arranged to provide an indication when registration with another such device is achieved. The indication may be audible or visible in nature.

Adjacent contacting edges of devices may be adapted to fit together or interlock only when correctly orientated so that both display said visual display material the same way up (i.e. top to bottom). A rectangularly shaped device may be adapted to be orientated with a similar device adjacent to each of its four side edges, and the proximity sensor is then adapted to sense each adjacent device.

In an alternative embodiment of the invention, the devices are used in conjunction with a board, tray or base on which they are placed and which is capable of identifying the location and identity of each device and communicating this to a central control unit or one or more of the devices so that they can generate the sensory response. The board itself may consist of a screen which is able to generate a display appropriate for the particular application and/or to generate the sensory response. In this alternative embodiment of the invention, the individual devices may not need to incorporate the proximity sensor because of the location sensing ability of the board.

In the above alternative embodiment, the board may be adapted so that it can recharge individual devices when placed in contact with it. Furthermore, this recharging feature may be provided in a board not having the device location capability.

A device according to the invention may also incorporate a camera that allows an image to be captured, this image being used as said visual display material on a visual display unit also incorporated in the device, or the image can be used in a visual sensory response.

A device according to the invention may also incorporate a microphone to allow sound to be captured and used in an audio sensory response.

A device according to the invention may also incorporate data input means in the form of a handwriting recognition device to input words, letters, symbols or numbers for use in characterisation of the device or programming a sensory response to be produced by the device.

It will be appreciated that an audio sensory response, such as incorporated in any of the embodiments described above, may take the form of a directional or stereo/audio response by arranging that two or more devices are controlled simultaneously or sequentially to generate appropriate sounds.

Programming of each device may be achieved by any of a number of different methods including connection to memory media such as smart cards or memory sticks; via a personal computer or hand-held computing device; or via said communications unit. In one example, each device may make use of the communications unit to receive information from a television broadcast so that the device is adapted for use in conjunction with a television programme being broadcast.

A device according to the invention is preferably further adapted so that it incorporates a user sensor sensitive to touch and/or movement so that it can trigger a characterisation output when handled by a user. The characterisation output may comprise a visual or audio output or both.

Specific technologies that can be used in embodiments of the invention include networked distributed intelligent small computers known as Specks or Motes; micro-electromechanical-systems MEMs, especially for audio components and sensors; and ZigBee radio or similar communications technology.

A manually manipulable device according to the invention is, from one aspect, a computing unit and as such can be designed to be a thin client in a client-server relationship with some other entity.

In one embodiment, a manually manipulable device according to the invention comprises a 32 Bit RISC (or better) CPU, memory, a graphics processor, an audio processor, a communications processor, internal data storage, a rechargeable power source and a touch-sensitive audio-visual display unit. The CPU is preferably capable of processing 200 Million Instructions Per Second (MIPS) or better. The CPU can preferably address 16 Mb (or better) of Random Access Memory. The graphics processor and visual display will preferably be capable of rendering screen resolutions of 160.times.160 pixels (or better) in 8 bit colour (or better). Other versions will be able to process full motion video at 12.5 frames per second (or better) with 16 bit colour (or better) synchronised to audio. Other versions will have live video or still image capture via a built-in camera. The audio processor will preferably be capable of playback of 4 bit, 4 kHz mono audio (or better) and polyphonic tones. Enhanced versions will feature audio recording capability. The internal storage may be provided by Secure Digital (SD) cards, MultiMedia Cards (MMC) or a hard disc arrangement. The communications processor will preferably include support for industry standard wireless protocols including Bluetooth and in future will support other emergent protocols including IEEE 802.15.4 and other near field communication protocols. It is presently preferred that a manually manipulable device according to the invention will have a real time operating system (RTOS).

Video apparatus could for example involve the use of screens 5 cm.times.5 cm, but 8 cm.times.8 cm might also be acceptable. The screens could for example comprise thin film transistor TFT screens with an active matrix 2.5″ (4:3), a resolution 880.times.228 RGB delta, pixel size 56.5.times.164 HM, fully integrated single-phase analogue display drivers, signal input voltage 3V, driver frequency 3 MHz, driver power consumption 15 MW.

The power source is preferably a rechargeable battery and might comprise a photovoltaic generator.

The user sensor may also sense manipulation of the device by a user indicative of a positioning movement of the device requiring an assessment of its proximity relative to similar devices and the need to generate a sensory response corresponding to one of said arrangements of devices.

According to a further feature of the invention, each of said manually manipulable devices incorporates a visual display unit to display visual display material, and two or more of said devices are adapted to be arranged in a row so that said visual display material “reads” in a meaningful manner along said row. A similar device is locatable adjacent to one side of said row of devices, and thereby triggers a change in the visual display material on said similar device so that it matches that of said row of devices. For example, said similar device can be located below said row of devices to acquire a combination of characters from the row above it. This device displaying said combination of characters can then be re-used in a further row of devices to create a new combination of characters.

Each device may have an ON/OFF switch to allow it to be reset to a start up condition, for example, displaying initial pre-programmed visual display material.

BRIEF DESCRIPTION OF THE DRAWINGS

By way of example only, certain embodiments of the invention will now be described with reference to the accompanying drawings, in which:

FIG. 1 illustrates the external physical constitution of an interactive block;

FIG. 2 illustrates, conceptually, the internal constitution of the interactive block of FIG. 1,

FIG. 3 illustrates how blocks of the kind illustrated in FIG. 1 can be connected in registration with one another;

FIG. 4 illustrates how blocks of the kind shown in FIG. 1 can be used in a learning activity;

FIG. 5 illustrates schematically an interactive block; and

FIG. 6 illustrates schematically a tray or board which can interact with blocks of the kind shown in FIG. 5.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

One embodiment of the invention consists of a set of blocks, say 12 blocks, each being rectangular in shape and adapted to be positioned edge-to-edge with other blocks on either side (referred to as left-hand and right-hand edge) in the manner of a row, and top edge and bottom edge in the manner of a column. Each block incorporates a display screen over most of its front or upper surface, which forms part of an electronic visual display unit capable of displaying visual display material according to display data derived from a database. In this embodiment, the visual display material consists of a lower case letter of the alphabet which is displayed on the screen when the block is first activated. Each block may incorporate a switch that allows it to be activated to deactivated, and operation of the switch initiates a start-up condition in which a pre-programmed letter is displayed. Programming of the blocks may be such that different combinations in a row can spell out fifteen to twenty different words appropriate for teaching a young child to read.

Each block incorporates a means of displaying its orientation as far as top and bottom is concerned, which may invoke the shape of the block or an indicator displayed in the display screen.

Each block further incorporates a proximity sensor or sensor adapted to allow it so sense the proximity of another block aligned edge-to-edge with it, preferably involving contact between said adjacent edges, either at the left hand edge or right-hand edge or top edge or bottom edge. The proximity sensor, or other ID sensor means independent of it, is adapted to sense the identity of each adjacent block.

Each block further incorporates a touch and/or movement sensor.

Each block further incorporates a wireless communications unit through which it can communicate with another block to transmit information relating to its own identity and visual display material and the identity and location of adjacent blocks and to receive information causing the visual display unit to change the visual display unit material.

Each block preferably further incorporates an audio generator which is adapted to produce an audio response in accordance with internal programming information received via the wireless communications unit.

It will be appreciated that a block with the communications, visual display and audio generator capability described above can be readily implemented using mobile telephone technology. Proximity sensors, ID sensors and touch and movement sensors can also be readily implemented using known technology. It will be appreciated that each block has its own power supply and incorporates a processor or processors which provide the required functionality.

A set of blocks is adapted to be sufficient in itself to provide the functionality described below with the processors operating in accordance with pre-programmed instructions and the inputs from the sensors of each so as to produce visual and audio responses in the blocks.

The constitution of an example one of the blocks is shown in FIGS. 1, 2 and 5. The internal construction of a block is shown conceptually in FIG. 2 and in block diagram form in FIG. 5. FIG. 3 illustrates how blocks of this kind can be placed in registration with one another both vertically and horizontally.

FIG. 5 illustrates the main components of a block. It will, of course, be apparent to the skilled person that this is a high level diagram illustrating only key components of the block. As shown in FIG. 5, a block 500 comprises a processor 510, a memory 512, an RF transceiver 514, a screen 516, a speaker 518, a magnetic switch 520, a touch sensor 522, a movement sensor 524, a docking port 526 and a battery 528. The RF transceiver 514 enables the block 500 to communicate wirelessly with other, at least similar, blocks in the vicinity. The screen 516 and the speaker 518 allow visual and audio information to be presented to a user of the block 500. The magnetic switch 520 is activated by the proximity of another, at least similar, block. The touch sensor 522 is provided at the exterior of the block 500 to detect a user touching at least that area of the block 500. The movement switch 524 detects movement of the block 500 by a user. The docking port 526 is for receiving a memory card to load software/data into the block 500. The block 500 also includes a battery 528 that provides power to allow the various devices within the block to operate. The processor 510 processes, with the aid memory 512, information received from the RF transceiver 514, the switch 520, the touch sensor 522, the movement sensor 524 and the docking port 526 to cause, as appropriate, the RF transceiver 514 to communicate with other blocks and/or cause the screen 516 and/or the speaker 518 to present information to a user of the block 500.

FIG. 6 shows a tray 600 for use with blocks, e.g. 610 to 616 of the kind described above with respect to FIGS. 1, 2 and 5. The board 600 comprises a detector 618 for determining the location and identity of blocks placed on the board. The board 600 also includes a charger for recharging the batteries of blocks that are placed on the board. The board also includes a screen 622 and is configured to present information to a user via the screen in response to interactions of the user with blocks on the board.

Examples of how the set of blocks can be used as alphabet blocks will now be now described.

Sam is four and a half. She's just started in her reception year at school where she's learning to read and write. Her parents are keen to help her learn at home and buy her a set of blocks with some preloaded reading software appropriate for her age.

Sam opens the box and takes out the blocks. Her parents are standing over, curious about how they work.

Each is displaying a different lower case letter.

She goes to pick one up and the unit sounds the letter it is displaying. For example, ‘/c/’. Moving each of the blocks she realises they all do the same.

In an alternative option, if there's 15 seconds inactivity, one block could say ‘Try spelling a word, how about cat’. Alternatively pressing on a block could say, ‘c sounds like /c/. /c/ is for cat. Move the blocks together to spell cat?’

Sam puts two of the blocks next to each other. Starting with the one on the left, the blocks read in turn the letters they are displaying. For example ‘/d/, /o/’. They then read the combined sound. For this example the blocks would say ‘do’.

When she puts three ‘random’ letters together ('/c/, /f/, /g/'), they make no sound.

She plays around with some different combinations until a word is spelt. For example, ‘/c/, /a/, /t/. You've spelt cat. Well done.’ At this point a cat leaps onto the screen, runs around and miaows.

In an alternative option, the blocks prompt the child what to do next? For example, Now you can copy the word you've made onto its own block, by placing one below. Or you can try and spell another word.'

When Sam puts another block below the word she has spelt, the word jumps down onto that single block. It's says ‘cat’ when she presses it.

The three blocks that originally spelt the word are now free to be used for another word.

As described above, each block is individually responsive to touch or movement and reacts audibly and visually depending upon what it displays.

If each block is responsive to both truck and movement separately, then each can have a secondary response, such as giving an example of use.

If a letter is displayed, e.g. “c”, the block sounds the letter as in it is said in the alphabet and phonetically. For example, ‘C. C sounds like /c/ for cat’. An animation may play on the screen relating to the letter and the example given. A secondary response might suggest what the user can do next? For example, ‘Can you spell Cat?’

If a word is displayed e.g. “cat”, the block sounds the phonetic letters for the word. For example, ‘/c/, /a/, /t/ spells cat’. An animation relating to the word plays on the screen. A secondary response might suggest the spelling of another word from the available letters if this is possible.

If a phonetic sound is displayed e.g. “ch”, the block sounds the combined phonetic sound ‘/ch/ as in lunch’. The screen displays an animation of some food being eaten.

When blocks are placed next to each other they react depending what is on each. This could be a phonetic sound e.g. ‘/ch/’, a word e.g. ‘cat’ or random letters e.g. ‘/k/, /r/, /f/’.

If the user places individual blocks alongside each other then they respond according to the combination of letters they display.

If a phonetic sound is created “ch”, the blocks sound the combined sound, ‘/ch/’. They could also give a short example of use ‘/ch/ as in lunch, yum, yum, yum’.

If a word is created “cat”, the blocks sound the individual letters followed by the word. For example, ‘/c/, /a/, /t/, spells cat. Well done, you've spelt cat’. The displays play a short animation. In this example a picture of a cat running between the two blocks. This happens whenever one of the joined blocks are pressed.

If a new word is created (plural or completely new) by adding a letter or letters to a current word of phonetic sound, the response might be, for example, ‘/c/, /a/, /r/, /t/, spells cart. Are you coming for a ride?’ or ‘/c, /a/, /t/, /s/ spells cats. Here they come!’. The displays animate according to the word spelt if the word has an associated animation in database. So in the above examples, a horse and cart could drive on and off the screens, or several cats could start playing around.

If a random set of letters are placed next to each other. For example ‘/d/, /f/, /r/, /g/’, no sound is generated and no animation is displayed.

Animation and sound will only be available for some of the words that can be created using the blocks, as stated in a related response database held in one or each block or a central control unit.

If a user places one block adjacent the top edge of another, the lower block inherits the property of the upper block. Placing multiple blocks above or below will also cause a reaction between the blocks. For example, if the user places one block above another, and the top block shows ‘/b/’ and the lower block shows ‘/b/’, the lower block will also become a ‘/b/’.

A user can place a word spelt out over several blocks onto one block by placing a block below. This could also be used to join a ‘/c/’ and an ‘/h/’ on a single ‘/ch/’ block.

If a user has spelt a word or phonetic sound using three individual blocks, for example, ‘/c/’, ‘/a/’ and ‘/t/’ spelling ‘cat’, the user can then place a fourth block anywhere under the three letter blocks and the word “cat” moves onto a single block. However, if a user tries to copy two random letters onto a single block it will not work. For example ‘/g/’ and ‘/f/’ cannot be joined on a single ‘/gf/’ block.

Likewise if the user has two word blocks that don't make a third word, they cannot be copied onto a single block. For example ‘cat’ and ‘sat’ cannot be joined to make a ‘catsat’ block.

If a user has the word cat on a single block and wants to split it into three separate letters, they need to place three blocks below the word block. The three letters each go into their own block in right to left order below.

An example of use of a set of alphabet blocks operating according to the above principles is illustrated in FIG. 4, in a number of steps 1-6.

1. Blocks are taken out of the box and arranged on the floor.

2. User puts ‘/c/’ and ‘/h/’ together, the blocks sound ‘/ch/’. They put ‘/g/’ underneath and copy ‘/ch/’ onto it. Trying to copy ‘/t/’, ‘/m/’ onto ‘/g/’ doesn't work.

3. ‘/a/’ and ‘/t/’ are joined to make ‘at’ and copied onto a single block.

4. ‘/m/’ is put in front of ‘at’ to make ‘mat’. The individual ‘/a/’ and ‘/t/’ blocks are still joined to the top of ‘at’, but have no direct effect to the ‘/m/’ as they are not directly above but to one side. ‘/u/’ is put below the ‘/m/’ of ‘mat’ and ‘mat’ is copied onto the single block, which is then removed (not illustrated).

5. A ‘/s/’ block is put in front of the ‘/a/’ and ‘/t/’ blocks to spell ‘sat’. As the ‘/m/’ of ‘mat’ is now below the ‘/s/’ block the word ‘sat’ is copied onto it. ‘sat’ is also copied onto the ‘at’ block. The two ‘sat’ blocks don't interact with each other as a new word or sound hasn't been created. Likewise when a ‘r’ block is placed below either of the ‘sat’ blocks nothing is copied down.

6. Using the blocks here is a chain of various words that can be created following the principles described in the functional specifications.

The invention is applicable to diverse areas, which include but are not limited to, play, entertainment, adornment and decoration, environment, industry and learning (of, for example, languages, mathematics and musical skills/knowledge).

Play applications may include a variety of playful games using the blocks and, optionally, a tray of the type mentioned in the introduction. These include new games as well as enhancements of typical existing board and card games with additional features (by virtue of the fact the pieces (blocks) can change their image and emit sounds) and the board (interactive base) can also change its image. Further, new forms of toy such as farmyards and zoos can be created and become elements of animated stories.

In relation to adornment and decoration, in the educational context, IA blocks can be worn as badges that can enable students to role play their various functions (letters, sounds, numbers) and interact with other badge-wearing children to form words, tunes and equations. Beyond this, IA blocks have implicit emotive, aesthetic, interactive, and descriptive capabilities. Blocks in combination can be used to trigger social and artistic interactions between people or create more complex installations.

In environment and industrial settings variations of the devices can enable audio and visual data/systems alone or in combination (e.g. for health and safety measurement and control). 

1. A method of controllably presenting changeable, processor-generated individual characterizations presented on each of a plurality of objects that selectively interact, the method comprising: generating and displaying under powered processor-control first visual display material on a first movable object, the first visual display material having a first changeable individual characterization having a first property; sensing proximity and relative position of second visual display material generated and displayed under powered processor-control on a second movable object separate to the first movable object, the second object brought into processor-resolvable interacting proximity with the first moveable object by manipulation of one or more of the first movable object and the second movable object, the second visual display material having a second changeable individual characterization independent to the first individual characterization, the second changeable individual characterization having a second property; in response to processor-resolved interaction between said first and second changeable individual characterizations arising from sensed proximity and relative position of the first and second objects, generating a user-perceivable sensory response from a response generator, wherein the user-perceivable sensory response is dependent upon said sensed relative positions of the first visual display material to the second visual display material and is indicative of a contextual relationship that arises between said first property of the first changeable individual characterizations and the second property of the second changeable individual characterizations; and under processor-control, selectively and autonomously changing with time the individual characterizations on at least one of the first and second objects such that the first property and the second property change to allow different processor-resolvable interactions to take place between the first and second objects, which different processor-resolvable interactions give rise to new user-perceivable sensory responses.
 2. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein the change in property and individual characterization presented by one of the plurality of objects is dependent upon the processor-resolved interaction and contextual relationship between the first changeable individual characterization presented on the first object and the second changeable individual characterization presented on the second object.
 3. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein the change to the first property and/or the second property includes an auditory change.
 4. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein the change to the first property and/or the second property includes a visual change.
 5. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein the user-perceivable sensory response is a phonetic sound produced by combined interaction of said first and second changeable individual characterizations and their respective first and second meanings.
 6. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein generating the user-perceivable sensory response further generates: an audible representation of the first changeable individual characterization; and an audible representation of the second changeable individual characterization.
 7. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, the method further comprising: under processor-control, selectively changing with time said changeable individual characterizations displayed on said plurality of objects based upon: i) nearby detection and relative position of objects; and ii) individual characterizations presented by interacting objects at the time of their detection and interaction.
 8. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein the user-perceivable sensory response is generated for only meaningful non-random interactions between said first and second changeable individual characterizations.
 9. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein the user-perceivable sensory response generated from the response generator includes an audible response, a visual response or a combination of an audible and visual response.
 10. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 8, wherein the user-perceivable sensory response includes a related visual animation.
 11. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, wherein generating the user-perceivable sensory response includes generating at least one of: a phoneme; a letter, word, phrase or sentence; speech relating to mathematical properties of a visually presented number; and an audio musical response corresponding to a musical symbol.
 12. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, further comprising: arranging said first and second objects in a line so that said first visual display material and said second visual display material reads in a meaningful manner along said line; and locating a third object adjacent to one side of said line of objects, the third object having a third changeable individual characterization presented as third visual display material, the step of adjacently locating causing the third visual display material presented on said third object to change to take on the combination of said first visual display material and said second visual display material that reads in the meaningful manner along said line.
 13. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, further comprising: locating a third object proximate to the first and second objects, the step of locating causing positioning of the third object in one of a multiplicity of different positions below the first and second objects, the third object having a third changeable individual characterization; determining relative positions between the first, second and third objects; in the event that said relative position between the first and second objects results in production of a non-random meaningful, interaction between at least the first and second individual characterizations that produces one of a phoneme, a word a mathematical property or a musical response, effecting a processor-controlled change to the third changeable individual characterization presented on the third object by generating a new changeable individual characterization that is presented on the third object and which new changeable individual characterization reflects: i) the meaningful interaction taking place between the first and second individual characterizations; and ii) the relative position between the first, second and third objects.
 14. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 12, wherein each object is arranged to generate and display a changeable individual characterization in the form of: at least one letter; a word; a number; a mathematical symbol; or a musical symbol.
 15. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, further comprising: selectively programming each of the plurality of objects to present over time a multiplicity of properties under processor-control.
 16. The method of controllably presenting changeable, processor-generated individual characterizations according to claim 1, further comprising: based on relative position between the first and second movable objects, having the first movable object inherit properties associated with at least the second changeable individual characterization of the second movable object.
 17. A method of controllably presenting changeable, processor-generated individual characterizations presented on each of a plurality of objects that selectively interact, the method comprising: generating and presenting under powered processor-control first visual display material on a processor-controlled object, the first visual display material having a first changeable individual characterization with a first property; sensing proximity and relative position of second visual display material generated and presented under processor-control on a second object movable independently of said processor-controlled object, the second object brought into processor-resolvable interacting proximity with said processor-controlled object by manipulation of one or more of said processor-controlled object and the second object, the second visual display material having a processor-controlled second changeable individual characterization independent of the first individual characterization, the second changeable individual characterization having a second property; sensing proximity and relative position of third visual display material generated and presented under processor-control on a third object movable independently of said processor-controlled object, the third object brought into processor-resolvable interacting proximity with said processor-controlled object by its relative manipulation with respect to the second object, the third visual display material having a processor-controlled third changeable individual characterization independent of the first and second individual characterizations, the third changeable individual characterization having a third property, the second and third properties of the second and third objects interacting with one another when located side-by-side in a line to produce a combination; under processor control changing the first changeable individual characterization with the first property to a fourth changeable individual characterization with a fourth property such that the fourth changeable individual characterization is presented on said processor-controlled object, the fourth property different to the first property, the fourth individual characterization being the combination inherited from the second and third individual characterizations provided that the in-line side-by-side combination has a contextual relevance that is not random; and determining new processor-resolvable interactions involving said processor-controlled object now having the fourth changeable individual characterization and generating and outputting audible and/or visual user-perceivable sensory responses from a response generator to reflect contextually relevant processor-resolvable interactions that reflect and/or involve the fourth changeable individual characterization.
 18. The method of controllably presenting changeable, processor-generated individual characterizations of claim 17, further comprising: assembling a first line of objects containing only the processor-controlled object and assembling a second line of objects contains the second and third objects but not the processor-controlled object; determining that the first and second lines are interacting; and determining whether the second and third changeable individual characterizations combine to provide a contextually relevant combination that is not random, subject to the second and third changeable individual characterizations combining to provide a contextually relevant combination that is not random, causing the first changeable individual characterization to change to the fourth changeable individual characterization by inheriting the contextually relevant combination based on an edge justification determined by the processor-controlled object in the first line relative to the contextually relevant combination in the second line.
 19. The method of controllably presenting changeable, processor-generated individual characterizations of claim 17, wherein the contextually relevant combination inherited as the fourth changeable individual characterization includes at least the second and third changeable individual characterizations.
 20. The method of controllably presenting changeable, processor-generated individual characterizations of claim 17, further comprising: assembling a first line of objects containing only the processor-controlled object and assembling a second line of objects containing at least the second and third objects but not the processor-controlled object; determining that the first and second lines are interacting; and determining whether at least the second and third changeable individual characterizations combine to provide a contextually relevant combination that is not random, subject to the second and third changeable individual characterizations combining to provide a contextually relevant combination that is not random, causing the first changeable individual characterization to the change to the fourth changeable individual characterization by inheriting the contextually relevant combination based on an edge justification determined by the processor-controlled object in the first line relative to the contextually relevant combination in the second line.
 21. A method of controllably presenting changeable, processor-generated individual characterizations presented on each of a plurality of objects that selectively interact, the method comprising: generating and presenting under powered processor-control first visual display material on a processor-controlled object, the first visual display material having a first changeable individual characterization with a first property; sensing proximity and relative position of second visual display material generated and presented under processor-control on a second object movable independently of said processor-controlled object, the second object brought into processor-resolvable interacting proximity with said processor-controlled object by manipulation of one or more of said processor-controlled object and the second object, the second visual display material having a processor-controlled second changeable individual characterization independent of the first individual characterization, the second changeable individual characterization having a second property; sensing proximity and relative position of third visual display material generated and presented under processor-control on a third object movable independently of said processor-controlled object, the third object brought into processor-resolvable interacting proximity with said processor-controlled object by its relative manipulation with respect to the second object, the third visual display material having a processor-controlled third changeable individual characterization independent of the first and second individual characterizations, the third changeable individual characterization having a third property, the second and third properties of the second and third objects interacting with one another when located side-by-side in a line to produce a combination; sensing proximity and relative position of fourth visual display material generated and presented under processor-control on a fourth object movable independently of said processor-controlled object, the fourth object brought into processor-resolvable interacting proximity with said processor-controlled object by its relative manipulation with respect to the second and third object, the fourth visual display material having a processor-controlled fourth changeable individual characterization independent of the first, second and third individual characterizations, the fourth changeable individual characterization having a fourth property, wherein the second, third and fourth properties of the second, third and fourth objects interacting with one another when located side-by-side in a line to produce a combination; under processor control changing the first changeable individual characterization with the first property to a fifth changeable individual characterization with a fifth property such that the fifth changeable individual characterization is presented on said processor-controlled object, the fifth property different to the first property, the fifth individual characterization being the combination inherited from the second, third and fourth individual characterizations provided that the in-line side-by-side combination has a contextual relevance that is not random; and determining new processor-resolvable interactions involving said processor-controlled object now having the fifth changeable individual characterization and generating and outputting audible and/or visual user-perceivable sensory responses from a response generator to reflect contextually relevant processor-resolvable interactions that reflect and/or involve the fifth changeable individual characterization.
 22. The method of controllably presenting changeable, processor-generated individual characterizations of claim 21, further comprising: assembling a first line of objects containing only the processor-controlled object and assembling a second line of objects containing the second, third and fourth objects but not the processor-controlled object; determining whether the first and second lines are interacting; and determining whether the second, third and fourth changeable individual characterizations combine to provide a contextually relevant combination that is not random, subject to the second, third and fourth changeable individual characterizations combining to provide a contextually relevant combination that is not random, causing the first changeable individual characterization to the change to the fifth changeable individual characterization by inheriting the contextually relevant combination based on an edge justification determined by the processor-controlled object in the first line relative to the contextually relevant combination in the second line.
 23. The method of controllably presenting changeable, processor-generated individual characterizations of claim 21, wherein the contextually relevant combination inherited as the fifth changeable individual characterization includes at least the second, third and fourth changeable individual characterizations.
 24. The method of controllably presenting changeable, processor-generated individual characterizations of claim 21, further comprising: inheriting and displaying a word produced from multiple similar interacting objects positioned in the line above said processor-controlled object.
 25. The method of controllably presenting changeable, processor-generated individual characterizations of claim 17, further comprising: inheriting phonetic properties produced from at least two similar interacting objects positioned in a line above said processor-controlled object and provided that interacting properties of the at two similar objects combine to provide a non-random phonetically meaningful combination. 